G6PD Deficiency Flashcards
Glucose-6-phosphate dehydrogenase deficiency is an X-linked inherited disorder that predisposes to .. anaemia.
Glucose-6-phosphate dehydrogenase deficiency is an X-linked inherited disorder that predisposes to haemolytic anaemia.
G6PD deficiency
OVERVIEW
Glucose-6-phosphate dehydrogenase (G6PD) deficiency is one of the inherited haemolytic anaemias. It is an X-linked inherited disorder due to a genetic variant (i.e. mutation) in the gene that encodes the protein G6PD located on the long arm of the X chromosome.
G6PD is needed for the formation of nicotinamide adenine dinucleotide phosphate (NADPH) that is used to maintain stores of glutathione in red blood cells that has a crucial role in preventing oxidative damage. The condition is usually asymptomatic but characterised by episodes of anaemia due to haemolysis when red blood cells are exposed to oxidative stress. This classically occurs through exposure to certain drugs (e.g. the antimalarial drug primaquine).
Worldwide, G6PD deficiency affects around … people
Worldwide, G6PD deficiency affects around 400-500 million people.
Epidemiology
G6PD DEFICIENCY
G6PD deficiency is seen across the world, but it is most commonly located in populations within the tropical and subtropical regions of Africa, Europe, and Asia. Certain populations have a high prevalence (e.g. Kurdish jews). The condition is usually seen in areas with a high prevalence of malaria. This has led to the hypothesis of a possible protective mechanism against the parasite.
G6PD deficiency - what gender is it seen in predominantly?
As the condition is X-linked, it is predominantly seen in males. Rarely females who are heterozygous (i.e. inherited one abnormal G6PD gene) may be affected due to skewed lyonisation of the X chromosome (discussed below), but the majority are asymptomatic carriers. In areas of high prevalence, females may be homozygous (i.e. inherited two abnormal G6PD genes) leading to the development of the disorder.
G6PD is an …-linked inherited disorder.
G6PD is an X-linked inherited disorder.
Rarely, females who are heterozygous may develop features of … deficiency. This is because of lyonisation of the X chromosome (discussed below).
Rarely, females who are heterozygous may develop features of G6PD deficiency. This is because of lyonisation of the X chromosome (discussed below).
Lyonisation of the X chromosome
G6PD deficiency
Lyonisation, also known as X-inactivation, is a biological process in which one of the X chromosomes in each cell of a female is ‘switched-off’ or ‘inactivated’. This is to prevent each cell from having twice as many gene products from the X chromosomes in females.
The choice of which X chromosome is inactivated is random. Therefore, if the chromosome that is left after inactivation has an abnormal gene, this will be expressed in the cell. This is usually not a problem because enough cells have the normal gene product through random inactivation. In females who are heterozygous for G6PD deficiency, G6PD enzymatic activity may be grossly deficient if there is skewed inactivation towards the X chromosome with the normal G6PD gene.
The gene for G6PD encodes a protein with 515 amino acids. There are > 200 genetic variants that can affect this gene leading to a variable reduction in the enzyme activity of the G6PD protein. The majority of these variants are single amino acid changes (e.g. missense point mutations).
The World Health Organisation can classify these hundreds of variants depending on the effect it has on G6PD enzymatic activity.
Class I variants: severe enzyme deficiency (<10%). Chronic haemolytic anaemia, but thankfully rare.
Class II variants: severe enzyme deficiency. Usually, only intermittent haemolysis when exposed to precipitants.
Class III variants: moderate enzyme deficiency (10-60%). Intermittent haemolysis, usually when exposed to precipitants.
Class IV variants: no enzyme deficiency or haemolysis.
Class V variants: increased enzyme activity.
G6PD is important to prevent … stress in red blood cells.
G6PD is important to prevent oxidate stress in red blood cells.
A large number of medications can precipitant oxidative injury in patients with G6PD deficiency leading to severe haemolysis. It is essential to check whether medications can be used safely in patients with G6PD deficiency prior to prescribing. Some drugs are associated with a ‘definite risk’ of causing haemolysis, whereas others are associated with a ‘possible risk’.
Commonly implicated medications include:
Antibiotics: nitrofurantoin, fluoroquinolones, sulphonamides
Antimalarials: primaquine, chloroquine (possible), quinine (possible)
Other: Dapsone, Methylene blue, Sulfonylureas, Rasburicase
Classically fava beans (i.e. broad beans) have been shown to induce …. The development of acute .. following fava bean ingestion has been referred to as ‘favism’.
Classically fava beans (i.e. broad beans) have been shown to induce haemolysis. The development of acute haemolysis following fava bean ingestion has been referred to as ‘favism’.
Commonly infections have been shown to precipitant haemolysis in patients with G6PD deficiency. This includes a variety of organisms and sites of infection. Other factors can include diabetic ketoacidosis and …
Commonly infections have been shown to precipitant haemolysis in patients with G6PD deficiency. This includes a variety of organisms and sites of infection. Other factors can include diabetic ketoacidosis and acute kidney injury.
There is a wide spectrum of severity in G6PD deficiency but the majority of patients are …
There is a wide spectrum of severity in G6PD deficiency but the majority of patients are asymptomatic between episodes.
Patients with G6PD deficiency are usually asymptomatic. Clinical features may develop when patients are exposed to oxidative stress leading to haemolysis and symptoms of anaemia. The severity of symptoms depends on the severity of haemolysis.
There may be a history of drug-induced …, gallstone disease or … jaundice.
Patients with G6PD deficiency are usually asymptomatic. Clinical features may develop when patients are exposed to oxidative stress leading to haemolysis and symptoms of anaemia. The severity of symptoms depends on the severity of haemolysis.
There may be a history of drug-induced haemolysis, gallstone disease or neonatal jaundice.